Industrial processes allylamines

Alkylation of ammonia is sometimes employed in industrial processes the resulting mixture of amines is separated by distillation. The ultimate starting materials for the industrial preparation of allylamine are propene, chlorine, and ammonia. Write a series of equations showing the industrial preparation of allylamine from these starting materials. (Allylamine has a number of uses, including the preparation of the diuretic drugs meralluride and mercaptomerin.)... 

During the past decade, metal-catalyzed asymmetric reactions have become one of the indispensable synthetic methodologies in academic and industrial fields. The asymmetric isomerization of allylamine to an optically active enamine is a typical example of the successful application of basic research to an industrial process. We believe that Takasago s successful development of large-scale asymmetric catalysis will have a great impact on both synthetic chemistry and the fine chemical industries. The Rh-BINAP catalysts, though very expensive, have become one of the cheapest catalysts in the chemical industry through extensive process development. 

Addition reactions to olefins can be used both for the construction and for the functionalization of molecules. Accordingly, chiral catalysts have been developed for many different types of reactions, often with very high enantioselectiv-ity. Unfortunately, most either have a narrow synthetic scope or are not yet developed for immediate industrial application due to insufficient activities and/ or productivities. These reactions include hydrocarbonylation [Ilf], hydrosilyla-tion [12 i], hydroboration [12j], hydrocyanation [12 k], Michael addition [11 g, 121, 12 m], Diels-Alder reaction [11 h, 12n] and the insertion of carbenes in C-H bonds [Hi, 12p, 12q, 38], Cyclopropanation [Hi, 12p, 12q] and the isomerization of allylamines [12 s] are already used commercially for the manufacture of Cilastatin (one of the first industrial processes) [12 r], and citronellol and menthol (presently the second largest enantioselective process) [12t] respectively. 

There are rather few reactions that can be described as fully atom economical , i.e. when there are no co-products and all the atoms in the starting material(s) appear in the product(s). However, all isomerisation reactions necessarily fall into this category. The use of a transition metal to catalyse such a process with an appropriate substrate brings the possibility of effecting asymmetric isomerisation, a very efficient method to generate enantiomerically enriched products. Indeed, the asymmetric Rh-catalysed isomerisation of an allylamine to an enamine, which proceeds in over 96% ee, was scaled up a number of years ago for industrial production. The enamine product forms a multi-tonne feedstock for menthol and perfumery synthesis. In contrast, the cyclo-isomerisation of dienes, an equally atom-economical process that generates synthetically useful cyclic products, has seen relatively little development despite the reaction having been known for some 30 years. 

Chiral diphosphanes (diphosphines) occupy a special place among the chiral auxiliaries described so far because of their efficiency and for historical reasons. Typically, diphosphines are involved industrially in the enantioselective hydrogenation of C=C, C=0, and C=N bonds, and in the isomerization of an allylamine [4]. The design of the ligand is intimately connected to the catalytic process in which the ligand will be involved. In addition, the combination of the metallic... 

Asymmetric isomerization of allylamines is performed with high enantioselectivity [57]. This process is applied to the industrial production of L-menthol from diethylger-anylamine by the Takasago Perfumery Company (eq (48)). 

---